U.S. patent number 8,908,309 [Application Number 13/906,648] was granted by the patent office on 2014-12-09 for system, method and apparatus for master pattern generation, including servo patterns, for ultra-high density discrete track media using e-beam and self-assembly of block copolymer microdomains.
This patent grant is currently assigned to HGST Netherlands B.V.. The grantee listed for this patent is HGST Netherlands B.V.. Invention is credited to Thomas Robert Albrecht, Bruno Marchon, Ricardo Ruiz.
United States Patent |
8,908,309 |
Albrecht , et al. |
December 9, 2014 |
System, method and apparatus for master pattern generation,
including servo patterns, for ultra-high density discrete track
media using E-beam and self-assembly of block copolymer
microdomains
Abstract
A system, method, and apparatus for forming a high quality
master pattern for patterned media, including features to support
servo patterns, is disclosed. Block copolymer self-assembly is used
to facilitate the formation of a track pattern with narrower
tracks. E-beam lithography forms a chemical contrast pattern of
concentric rings, where the spacing of the rings is equal to an
integral multiple of the target track pitch. The rings include
regions within each servo sector header where the rings are offset
radially by a fraction of a track pitch. Self-assembly is performed
to form a new ring pattern at the target track pitch on top of the
chemical contrast pattern, including the radial offsets in the
servo sector headers. When this pattern is transferred to disks via
nanoimprinting and etching, it creates tracks separated by
nonmagnetic grooves, with the grooves and tracks including the
radial offset regions.
Inventors: |
Albrecht; Thomas Robert (San
Jose, CA), Marchon; Bruno (Palo Alto, CA), Ruiz;
Ricardo (Santa Clara, CA) |
Applicant: |
Name |
City |
State |
Country |
Type |
HGST Netherlands B.V. |
Amsterdam |
N/A |
NL |
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Assignee: |
HGST Netherlands B.V.
(Amsterdam, NL)
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Family
ID: |
42284651 |
Appl.
No.: |
13/906,648 |
Filed: |
May 31, 2013 |
Prior Publication Data
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Document
Identifier |
Publication Date |
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US 20130293979 A1 |
Nov 7, 2013 |
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Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
Issue Date |
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12345799 |
Dec 30, 2008 |
8475669 |
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Current U.S.
Class: |
360/48;
360/77.08; 360/16; 360/135 |
Current CPC
Class: |
G11B
5/5521 (20130101); G11B 5/59633 (20130101); G11B
27/322 (20130101) |
Current International
Class: |
G11B
5/09 (20060101); G11B 5/86 (20060101); G11B
5/596 (20060101); G11B 5/82 (20060101) |
References Cited
[Referenced By]
U.S. Patent Documents
Foreign Patent Documents
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1841514 |
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Oct 2006 |
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CN |
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2003109333 |
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Apr 2003 |
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JP |
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2004303302 |
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Oct 2004 |
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JP |
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2007272962 |
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Oct 2007 |
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JP |
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Other References
Kim et al. Macromolecules V 39 (2006) 5466-5470. cited by applicant
.
Naito, Katsuyuki et al, 2.5-Inch Disk Patterned Media Prepared by
an Artificially Assisted Self-Assembling Method, IEEE Transactions
on Magnetics, vol. 38, No. 5, Sep. 2002. cited by applicant .
Kikitsu, Akira et al, Recent Progress of Patterned Media, IEEE
Transactions on Magnetics, vol. 43, No. 9, Sep. 2007. cited by
applicant.
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Primary Examiner: Negron; Daniell L
Parent Case Text
CROSS-REFERENCE TO RELATED APPLICATION(S)
The present application is a divisional from U.S. patent
application Ser. No. 12/345,799, filed Dec. 30, 2008, entitled
"SYSTEM, METHOD AND APPARATUS FOR MASTER PATTERN GENERATION,
INCLUDING SERVO PATTERNS, FOR ULTRA-HIGH DENSITY DISCRETE TRACK
MEDIA USING E-BEAM AND SELF-ASSEMBLY OF BLOCK COPOLYMER
MICRODOMAINS," naming inventors Thomas Robert Albrecht, Bruno
Marchon and Ricardo Ruiz, which is incorporated by reference herein
in its entirety.
Claims
The invention claimed is:
1. A hard disk drive, comprising: an enclosure; a disk rotatably
mounted to the enclosure, the disk having patterned magnetic media
with pre-patterned data tracks that are substantially concentric,
and the data tracks have servo sectors with headers, wherein
portions of the headers are radially offset from the data tracks by
a fraction of a pitch of the data tracks within the servo sector
headers, and the fraction of the track pitch comprises an edge
dislocation with an odd Burgers vector b; the data tracks are
separated by nonmagnetic grooves, with the nonmagnetic grooves and
the data tracks including radially offset regions; the servo sector
headers include transition regions at a beginning and an end
thereof, and space is provided for bursts within the servo sector
headers and outside of the servo sector headers, such that the
transition regions may be ignored by servo decoders; and an
actuator having a transducer for reading data from the data
tracks.
2. A hard disk drive according to claim 1, wherein the
pre-patterned data tracks are formed by self-assembly, and the
patterned magnetic media comprises discrete track media.
3. A hard disk drive according to claim 1, wherein a target track
pitch is in a range of about 25 nm to about 100 nm.
4. A hard disk drive according to claim 1, wherein the fraction of
the track pitch is one-half track.
5. A hard disk drive according to claim 1, wherein the bursts
comprise A, B, C, and D bursts with straight, high quality edges at
nonmagnetic grooves to support a precise read head position
determination.
6. A hard disk drive according to claim 1, wherein the edge
dislocation is induced through one of: a line shift with b=1, a
line shift with b=3, T-junctions and a random pattern.
7. A disk for a hard disk drive, comprising: a substrate having
patterned magnetic media with pre-patterned data tracks that are
substantially concentric, and the data tracks have servo sectors
with headers, wherein portions of the headers are offset from the
data tracks by a fraction of a pitch of the data tracks within the
servo sector headers; and the fraction of the track pitch comprises
an edge dislocation with an odd Burgers vector b.
8. A disk according to claim 7, wherein the pre-patterned data
tracks are formed by self-assembly, and the patterned magnetic
media comprises discrete track media.
9. A disk according to claim 7, wherein the fraction of the track
pitch is one-half track.
10. A disk according to claim 7, wherein the servo sector headers
include transition regions at a beginning and an end thereof, and
space is provided for bursts within the servo sector headers and
outside of the servo sector headers, such that the transition
regions may be ignored by servo decoders.
11. A disk according to claim 10, wherein the bursts comprise A, B,
C, and D bursts with straight, high quality edges at nonmagnetic
grooves to support a precise read head position determination.
12. A disk according to claim 7, wherein the edge dislocation is
induced through one of: a line shift with b=1, a line shift with
b=3, T-junctions and a random pattern.
13. A master template for fabricating disks for hard disk drives,
comprising: a substrate having tracks of patterned media that are
substantially concentric, and the tracks have servo sectors with
headers, wherein portions of the headers are offset from the tracks
by a fraction of a pitch of the tracks within the servo sector
headers; the servo sector headers include transition regions at a
beginning and an end thereof, and space is provided for bursts
within the servo sector headers and outside of the servo sector
headers; and the fraction of the track pitch comprises an edge
dislocation with an odd Burgers vector b.
14. A master template according to claim 13, wherein the tracks are
formed by self-assembly, and the patterned media comprises discrete
track media.
15. A master template according to claim 13, wherein the fraction
of the track pitch is one-half track.
16. A master template according to claim 13, wherein the bursts
comprise A, B, C, and D bursts with straight, high quality edges to
support a precise read head position determination.
17. A master template according to claim 13, wherein the edge
dislocation is induced through one of: a line shift with b=1, a
line shift with b=3, T-junctions and a random pattern.
Description
BACKGROUND OF THE INVENTION
1. Technical Field
The present invention relates in general to the master patterns of
discrete track media and, in particular, to the formation of a high
quality discrete track media master pattern, including features to
support servo patterns.
2. Description of the Related Art
Nanoimprinting has developed into a high profile technology that
provides a pathway to the next generation of lithography and
patterned media such as discrete track media (DTM). The features of
nanoimprinting, such as pillars, pits, and tracks, are on the order
of about 10 nm in diameter and/or width. The capability of
transferring these nano-scaled features from a template, mold, or
stamper to a substrate has been demonstrated. A master is typically
used to generate the templates, and the templates are then used for
mass imprinting production to avoid damage to the valuable master
in any imprinting accident. Moreover, the potentials for
nanoimprinting in high throughput and low manufacturing cost could
trigger a paradigm shift in today's optical lithography
technology.
As described herein, fabrication of discrete track media (DTM),
like bit patterned media (BPM), may be accomplished by several
techniques. For example, one fabrication method includes: (1)
creating a master pattern on a master template, (2) high volume
replication of the master pattern via UV cure nanoimprinting, and
(3) etching transfer of the nanoimprinted pattern to the magnetic
layer on disks. Although this technique is workable, an improved
system, method and apparatus for forming high quality discrete
track media master patterns, including features to support servo
patterns for disk drive applications, would be desirable.
SUMMARY OF THE INVENTION
The invention comprises embodiments of a system, method, and
apparatus for forming a high quality, master pattern for patterned
media, such as discrete track media, including features to support
servo patterns. The use of block copolymer self-assembly
facilitates the formation of a track pattern with narrower tracks
than can be achieved by e-beam lithography alone. The invention
also produces a higher quality pattern than e-beam alone is capable
of producing. Furthermore, other features are formed so that servo
patterns are generated on the master disk in a manner that is
consistent with block copolymer self-assembly.
E-beam lithography may be used to form a chemical contrast pattern
of concentric rings, where the spacing of the rings is equal to an
integral multiple of the target track pitch. The rings include
regions within each servo sector header where the rings are offset
radially by a fraction of a track pitch. Self-assembly is
performed, which creates a new ring pattern at the target track
pitch on top of the chemical contrast pattern, including the radial
offsets in the servo sector headers, When this pattern is
transferred to disks via nanoimprinting and etching, it creates
tracks separated by nonmagnetic grooves, with the grooves and
tracks including the radial offset regions.
In one embodiment, the formation of the pattern starts with a
substrate having chemical contrast that provides different wetting
affinities to the constituent materials of a block copolymer to
direct the assembly of the block copolymer. One way to generate a
substrate with such chemical contrast is by depositing a thin film
on a substrate using a material that is either neutral or slightly
preferential toward one of the microdomain types for the intended
block copolymer self-assembly. E-beam resist is applied on top of
the film, and exposed to create narrow grooves in the resist and
developed. The sample is then subjected to an oxygen plasma or
other means of altering the chemical properties of the brush film
in the grooves where the film is not covered by resist. The e-beam
resist is then removed with a suitable solvent. The result is a
substrate with chemical contrast between the chemically modified
brush areas and the unmodified areas.
After creation of the chemical contrast pattern, a block copolymer
solution may be coated on top of the pattern and annealed. The
block copolymer material is chosen so that it will form striped
domains, and the spacing of the original e-beam contrast pattern is
chosen to be near a small integer multiple of the natural
periodicity of the annealed block copolymer. After annealing, the
block copolymer forms stripes at its natural period which are
generally parallel to and commensurate with the underlying contrast
pattern. Since the contrast pattern includes the offset regions,
the block copolymer lamellae will follow the shifts in the
pattern.
The foregoing and other objects and advantages of the present
invention will be apparent to those skilled in the art, in view of
the following detailed description of the present invention, taken
in conjunction with the appended claims and the accompanying
drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
So that the manner in which the features and advantages of the
present invention are attained and can be understood in more
detail, a more particular description of the invention briefly
summarized above may be had by reference to the embodiments thereof
that are illustrated in the appended drawings. However, the
drawings illustrate only some embodiments of the invention and
therefore are not to be considered limiting of its scope as the
invention may admit to other equally effective embodiments.
FIG. 1 is a schematic isometric view of one embodiment of a master
template constructed in accordance with the invention;
FIG. 2 is an enlarged schematic plan view of one embodiment of a
series of data tracks on a magnetic media disk illustrating
precursor lines, and is constructed in accordance with the
invention;
FIG. 3 is an enlarged schematic plan view of a servo section for
data tracks on a magnetic media disk, and is constructed in
accordance with the invention; and
FIGS. 4A-E are enlarged schematic plan views of various alternate
embodiments of servo sections for data tracks on magnetic media
disks, and are constructed in accordance with the invention.
DETAILED DESCRIPTION OF THE INVENTION
Referring to FIGS. 1-4E, embodiments of a system, method and
apparatus for forming a high quality, patterned media (e.g.,
discrete track media (DTM)) master pattern, disks and disk drives,
including features to support servo patterns, are disclosed. The
use of block copolymer self-assembly facilitates the formation of a
DTM track pattern with narrower tracks (i.e., higher tracks per
inch, or TPI) than can be achieved by e-beam lithography alone.
This system also produces a higher quality pattern (i.e., in
feature dimensional uniformity and placement tolerance) than e-beam
alone is capable of producing. Furthermore, other features are
formed so that servo patterns are generated on the master disk in a
manner that is consistent with block copolymer self-assembly.
E-beam lithography may be used to form a chemical contrast pattern
of substantially concentric rings 11 (FIG. 1) on a master template
(e.g., a silicon or quartz wafer 13). The rings may be slightly
eccentric or non-circular due to tolerances in patterning the
tracks and in mounting the disk in the drive. The spacing of the
rings is equal to an integral multiple of the target track pitch.
The rings 11 include regions 15 (FIG. 2) within each servo sector
header where the rings are offset radially by a fraction of a track
pitch. Self-assembly is performed, which creates a new ring pattern
at the target track pitch on top of the chemical contrast pattern,
including the radial offsets in the servo sector headers. When this
pattern is transferred to disks via nanoimprinting and etching, it
creates tracks separated by nonmagnetic grooves, with the grooves
and tracks including the radial offset regions.
The formation of the pattern starts with a substrate having
chemical contrast that provides different wetting affinities to the
constituent materials of a block copolymer to direct the assembly
of the block copolymer One way to generate a substrate with such
chemical contrast is by depositing a thin film on a substrate using
a material that is either neutral or slightly preferential toward
one of the microdomain types for the intended block copolymer
self-assembly.
For example, this film can be a polymer brush film. E-beam resist
is applied on top of the film, and exposed to create narrow (e.g.,
typically 30% of track pitch, with track pitch of 25-100 nm)
grooves (i.e., clear areas) in the resist and developed. In other
embodiments, a width of the open areas may range from about a same
width as that formed by the block copolymer to about 50% of a ring
spacing defined by the e-beam, with the target track pitch being in
a range of about 25 to 100 mm. The open areas in the resist expose
portions of the brush layer. The sample is then subjected to an
oxygen plasma or other means of altering the chemical properties of
the brush film (or even removing the brush film to expose the
substrate) in the grooves where the film is not covered by resist.
The e-beam resist is then removed with a suitable solvent. The
result is a substrate with chemical contrast between the chemically
modified (or removed) brush areas and the unmodified areas.
The patterns are concentric rings that represent the nonmagnetic
grooves between tracks on the finished DTM disk. The rings,
however, include short regions within what will become the servo
sector headers where the radii of the rings are increased or
decreased by a fraction of a track (e.g., 1/2 track is the simplest
case). This means that the track pattern on the finished disk will
include these radially-shifted regions within each intended servo
sector header.
Although some embodiments expose the e-beam features that will
correspond with the grooves on the finished disk, there are many
process steps between the e-beam exposure and the final disk where
the tone of the image can be reversed. Thus, the invention is not
limited to exposing what will become nonmagnetic grooves on the
finished disk. Moreover, the e-beam exposure creates rings at a
multiple of the track pitch on the finished disk, so it does not
expose all of the rings, whether track or groove, at this stage. In
addition, the concentric rings defined by e-beam do not necessarily
have to be continuous lines. The rings may be defined by, e.g.,
dotted lines, dashes, continuous lines, or combinations
thereof.
After creation of the chemical contrast pattern, a block copolymer
solution is coated on top of the pattern and annealed. The block
copolymer material is chosen so that it will form striped domains
(either a lamellar phase or cylindrical phase block copolymer would
serve this purpose), and the spacing of the original e-beam
contrast pattern is chosen to be near (e.g., within about 15% of) a
small integer multiple (e.g., 1.times., 2.times., 3.times., etc.)
of the natural periodicity of the annealed block copolymer. In some
embodiments, the polymeric material may comprise diblock copolymer,
triblock copolymer, an n-block copolymer, and a blend of block
copolymers and homopolymers. After annealing, the block copolymer
forms periodic stripes at its natural period which are generally
parallel to and commensurate (i.e., in registration) with the
underlying contrast pattern. Since the contrast pattern includes
the offset regions, the block copolymer lamellae will follow the
shifts in the pattern.
Within a transition region at the beginning and end of the shifted
region, it can be expected that the quality of the block copolymer
stripe pattern may be poor or the stripes may even be somewhat
disordered. Therefore the patterns are laid out in a manner where
there is ample room for the bursts within the shifted region and
outside of it, and the transition region can be ignored by the
servo decoder. For example, as shown in FIG. 3, the A, B, C, and D
bursts all have high quality (i.e., edges at the grooves are
straight, and properly registered with the underlying chemical
contrast pattern), which will support a precise head position
determination.
Providing these offsets allows a servowriting operation to create a
conventional quad burst pattern. In a quad burst pattern, there are
typically four burst zones, A, B, C and D, as shown in FIG. 3. Note
that the bursts A and B are written one-half track shifted relative
to the data track, such that the groove which becomes the boundary
(i.e., a circumferential curve separating A and B radially) is in
the center of the data track. As the read head passes over this
series of bursts, it is possible to determine the radial position
of the read head with respect to the data track center (this is the
conventional use of quad burst servo patterns).
The patterns are magnetized in a self-servowrite operation, wherein
the write head writes a burst (e.g., typically square wave) of
alternating polarity magnetization in the regions A-D shown in FIG.
3. In the servo writing operation, the write head needs to be
positioned over the tracks and follows the runout of the tracks.
This can be accomplished using conventional procedures, such as the
"Eclipse Locator" used by International Manufacturing &
Engineering Services Co., Ltd. (IMES) in their RD2 spin stand
system.
Although the quad burst pattern may be used, there are other more
efficient servo patterns that also may be employed. Some of these
also use a quadrature-type pattern where part of the pattern needs
to be laterally shifted. This invention applies to any servo
pattern that benefits from having a shifted region. Other
embodiments include "null" patterns, which actually use two "null"
regions arranged in quadrature like the AB-CD patterns of the quad
burst approach.
There are several options to achieve a line shift by one-half track
with a block copolymer striped pattern. Topologically, the line
shift by a half-track pitch is the result of an edge dislocation
with an odd Burgers vector b. There are multiple configurations for
the transition region that would lead to the shift of the tracks.
These configurations vary in the number of dislocations inserted in
the transition region, their signs and the magnitude of their
Burgers vectors. From energetic considerations, sets of
dislocations of opposite signs may be more stable. The various
configurations can provide stability for the pattern, control over
the length of the transition area and mechanical rigidity to the
pattern. The block copolymer stripes serve as a lithographic mask
and hence mechanical rigidity is also important. The length of the
transition region is controlled by the magnitude of the Burgers
vector.
A few examples for the distribution of dislocations in the
transition areas are shown in FIGS. 4A-E. Another option to induce
the transition is through T-junctions as shown in FIG. 4E. In a
T-junction, additional stripes can be inserted between the T's to
control the length of the transition region (and, possibly, add
code information). The transition region throughout the tracks
could be composed of a combination of various configurations. In
other embodiments, the edge dislocation is induced through one of:
a line shift with b=1, a line shift with b=3, T-junctions and a
random pattern.
Examples of line shifts by one-half track pitch by block copolymer
patterns. FIGS. 4A-C illustrate examples of pairs of opposite
dislocations of Burgers vector with a magnitude of one (1). The
number of pairs and the distance between dislocation cores are
varied. The transition length, however, is constant. FIG. 4D is an
example of a line shift with b=3.
In some embodiments, the stripe-forming block copolymers tend to
want to produce stripe patterns with proportions of about 50%. For
DTM, embodiments with proportions of about 70% (e.g.,
land-to-groove ratio on finished disk) are desirable. Thus, the
pattern may be biased to accomplish this by, e.g., modifying the
block copolymer material, modifying the pattern in a subsequent
processing step, etc. Subsequent modification options include
adjusting etching conditions (e.g., overetching or use of less
anisotropy in etching, which causes sideways as well as down
etching), and deposition of material onto structure after etching.
In some embodiments, conformal deposition of a thin film (e.g., by
chemical vapor deposition) may be used to coat sidewalls of grooves
as well as top and bottom. This technique tends to close up a
groove, depending on how thick of a film is deposited. This
technique may be used to readily convert a 50% structure into a 70%
structure.
In servowriting, it is often necessary to move in fractional track
steps. For example, to write the shifted quadrature part of the
track as used in this invention, the write head is shifted by a
half track. It is not desirable to shift suddenly during a single
revolution, since this requires head motion that is faster than
most mechanical actuators can provide. The shift may be displaced
over two revolutions, one with the head shifted a half track to
write the shifted regions, and another revolution to write the rest
of the track. This can simply be generalized to writing servo
patterns in multiple revolutions with fractional track shifts,
since different kinds of servo patterns may be used that require a
shift other than a half track. One option is to have two shifted
regions, one shifted by 1/3 track, and the second by 2/3 track.
While the invention has been shown or described in only some of its
forms, it should be apparent to those skilled in the art that it is
not so limited, but is susceptible to various changes without
departing from the scope of the invention. For example, the
invention may be employed to fabricate master templates, replicated
working templates, as well as finished disks for disk drives, In
addition, during the overall fabrication process, the desired
pattern may be transferred from annealed block copolymer films to
another surface or film since it is necessary to develop the
pattern. This may comprise selectively removing one of the two
phases of the block copolymer either with a wet etchant or a dry
reactive ion etch. This is analogous to developing photoresist,
where the exposed portion is selectively removed by the developer.
Moreover, modification of the thin film to make the chemical
contrast pattern may be performed in several ways (e.g., exposure
of the film to an oxygen plasma through openings in developed
e-beam resist). In alternate embodiments, simple direct e-beam
exposure of the thin film may be used, which modifies it without
need for further processing, or exposure to other kinds of plasmas,
notably fluorine.
* * * * *